EP0772273A1

EP0772273A1 - Sensor of the instant power dissipated in a power transistor

Info

Publication number: EP0772273A1
Application number: EP95830458A
Authority: EP
Inventors: Giorgio Chiozzi
Original assignee: STMicroelectronics SRL; SGS Thomson Microelectronics SRL
Current assignee: STMicroelectronics SRL
Priority date: 1995-10-31
Filing date: 1995-10-31
Publication date: 1997-05-07
Anticipated expiration: 2015-10-31
Also published as: DE69522454D1; EP0772273B1; US5917382A

Abstract

A sensor of instantaneous power dissipable through a power transistor (Pwr) of the MOS type connected between the output terminal (OUT) of a power stage and ground (GND). It comprises a MOS transistor (Q5) having its gate terminal connected to that of the power transistor, source terminal connected to ground, and drain terminal connected to a circuit node (N) which is coupled to the output terminal (OUT) by means of a current mirror circuit (D1,Q2) which includes a resistive element (R) in its input leg.

Connected to the circuit node is the base terminal of a bipolar transistor (Q4) which is respectively connected, through a diode (D3) and a constant current generator (Iref) between the output terminal and ground.

Description

This invention relates to protection devices for power elements included in integrated circuits, and specifically to devices for protecting final power transistors included in integrated circuits against outgoing overcurrents and overvoltages as may originate from shorts, for example.
The protection devices are integrated to the circuit which includes the power element to be protected, and accordingly, it should be possible to fabricate them using simple and economical technologies, it being further necessary that the protectors involve no losses of useful power as may restrict the dynamic range of the power element.
In addition, such devices should be able to provide reliable protection of a high degree.
A conventional type of protection device that fills these demands has a circuit construction which includes at least one active element thermally coupled to the power element to be protected. This active element is connected to a control circuit means operative to turn off the integrated circuit to which the power element belongs upon the active element sensing a temperature level of danger, indicative of excessive power being dissipated due to a condition of overvoltage or overcurrent.
This conventional type of protection, while being effective and reliable, is unsuitable where the abnormal conditions of operation are only temporary since, lacking any external action, the device would remain off all the same.
It is for this reason that protectors are most frequently used which, although more complicated circuit-wise, have their cut-in threshold tied to the level of the electrical quantities, i.e. current and voltage, that are related to the element to be protected, rather than to the level of heat dissipation. The level of such quantities is regulated to suit the dissipated instantaneous power, without the integrated circuit having to be turned off.
Such protection devices usually include circuit means for sensing and processing the value of the current flowing through the power element and of the voltage across it to produce, on a given threshold of values being exceeded, the activation of a threshold circuit, for example, so as to bring the current value through the power element down to a maximum value which would correspond to the threshold and be a function of the voltage value across the element.
The maximum value of the current which can be flowed through the power transistor without problems, and on which the sizing of the protection circuit would be dependent, is set by the physical characteristics of the same.
In general, for economical reasons, the users of integrated circuits that include power elements would size the external heat sinks for such elements to meet normal operation requirements, since short periods of large heat dissipation are well tolerated.
However, in a condition of protracted shorting, there exists a risk of the integrated circuit being damaged, and the surrounding material overheating and perhaps catching fire, from the heat generated and not adequately dissipated to the outside.
On the other hand, it would not be convenient to have the maximum current level through the power element decreased by lowering the cut-in threshold of the protection, because this would needlessly restrict the dynamic range of the circuit under normal operating conditions.
An example of a protection circuit of the type just outlined, for a power element in an integrated circuit, is disclosed in US Patent No. 4,623,950 to this Applicant.
Since power transistors fail when their working point moves out of their Safe Operating Area (SOA), which SOA is largely limited by the maximum dissipable power, it is important to be able to accurately measure the instantaneous power being dissipated by the transistors, so as to ensure proper operation of the transistors and best utilization of their potential for dissipation. It is vitally important that this measurement be dependent on the smallest possible number of process parameters, and independent of temperature. The sensing circuit means employed heretofore actually provide coarse power measurements. In fact, they usually are affected by temperature and several process parameters, and disallow full exploitation of the power transistors. A simple circuit is also of importance, whose design should allow for utmost reproducibility and least use of silicon area.
The underlying technical problem of this invention is to provide a sensing circuit (or sensor) for sensing the instantaneous power dissipable through a power transistor in an integrated circuit, which while having a simple construction and using up but a minimal amount of integration area, affords improved measuring accuracy over conventional sensing circuits, so that full use of the transistor dynamic range can be made.
This problem is solved by a dissipable instantaneous power sensing circuit as indicated above and defined in the characterizing portions of the appended claims to this specification.
The features and advantages of a sensor according to this invention will be apparent from the following description of an embodiment thereof, given by way of example and not of limitation with reference to the accompanying drawings.
In the drawings:

Figure 1 shows a circuit diagram of an instantaneous power sensor, according to the invention, for a power transistor;
Figures 2 and 3 illustrate further improvements on the circuit diagram of Figure 1; and
Figure 4 illustrates a possible application of a pair of sensors according to the invention to a power final stage of the push-pull type.

Shown in Figure 1 is a circuit diagram of a sensor according to the invention adapted to sense the instantaneous power dissipable through a power transistor, in this case a power transistor Pwr of the N-channel MOS type, as commonly used in the lower half-stage of a push-pull power final stage (Figure 4).
A typical application would be to audio power amplifiers arranged for driving loudspeakers.
The power transistor Pwr is connected by its drain and source terminals, respectively, between the output terminal OUT of the stage and ground.
Omitted from the simplified diagram of Figure 1, are control and bias circuit means which may be those normally used by the skilled in the art, and are supplied, through the output terminal SHORT of the sensor, the information about the instantaneous power being dissipated by the power transistor, which information can be conventionally processed by such circuit means to protect the power element in all situations, without needlessly restricting its dynamic range.
The sensing circuit comprises a bipolar transistor Q4 of the PNP type which has its emitter terminal coupled to the output terminal OUT of the stage through a diode D3, and its collector terminal coupled to ground through a reference current generator Iref.
The output terminal SHORT of the sensor is connected to a circuit node between the transistor Q4 and the current generator Iref.
Connected to the output terminal of the stage is a current mirror circuit, of which a first leg includes a diode D1 and a resistor R and is connected between the terminal OUT and ground, while the second leg includes a bipolar transistor Q2 of the NPN type which is connected by its collector and emitter terminals, respectively, between the terminal OUT and a circuit node N to which the base terminal of the transistor Q4 is connected.
In accordance with the invention, the sensor further comprises a transistor Q5 which, as shown in Figure 1, is of the N-channel MOS type, like the power transistor, and is driven (in this case through a common terminal GATE) in the same manner as the power transistor.
The transistor Q5 has its source and drain terminals respectively connected to ground and to the circuit node N.
The transistors Pwr and Q5 are applied the same gate voltage, and they can be operated in the same conditions of bias. Furthermore, the transistor Q5 can be much smaller than the power transistor and be integrated in tight thermal connection thereto.
The manner how the instantaneous power dissipated through the power transistor Pwr is sensed will now be discussed.
The voltage drop across the diode D1 is $V_{1} = V_{t} ln I \frac{_{1} + \frac{I_{2}}{β}}{I_{s}}$
and that across the base-emitter junction of Q2 is $V_{2} = V_{t} ln \frac{I_{2}}{I_{s 2}}$
while the collector current of Q4 is $I_{o} = I_{s} _{4} exp \frac{V_{4}}{V_{t}} = I_{s} _{3} exp \frac{V_{3}}{V_{t}}$
The voltage V₃ across D3 can be obtained from (3) above, by equating the logarithms of the second and third terms and solving for V₃, thus: $V_{3} = \frac{V_{t}}{2} ln [\frac{I_{s 4} (I_{1} I_{2} + \frac{I_{2}^{2}}{β})}{I_{s 1} I_{s 2} I_{s 3}}]$
Substituting the expression (4) in (3), the following expression for the output current is obtained $I_{0} = \sqrt{\frac{I_{s 3} I_{s 4}}{I_{s 1} I_{s 2}}} \sqrt{I_{1} I_{2} + \frac{I_{2}^{2}}{β}}$
It can be seen that the current flowed through the transistor Q5 "mirrors" the current passed from the power transistor Pwr, and that I₁ is proportional to the drain-source voltage: $I_{1} = \frac{V_{ds} - V_{be}}{R}; I_{2} = \frac{{(\frac{W}{L})}_{5}}{{(\frac{W}{L})}_{pwr}} I_{out}$
Taking equation (6), and since the dissipated instantaneous power is $P_{diss} {= I}_{out} V_{ds}$
, (5) can be re-written as follows: $I_{0} = \sqrt{\frac{I_{s 3} I_{s 4}}{I_{s 1} I_{s 2}} \frac{1}{R} \frac{{(\frac{W}{L})}_{5}}{{(\frac{W}{L})}_{pwr}}} \sqrt{P_{diss} (1- \frac{V_{be}}{V_{ds}}) + \frac{P_{diss}^{2}}{V_{out}^{2}} \frac{R}{β} \frac{{(\frac{W}{L})}_{5}}{{(\frac{W}{L})}_{pwr}}}$
The last term under the root line in (7) takes account of the contribution from the base current of Q2 which, however, is trivial. Thus (7) becomes, as a coarse approximation $I_{0} = \sqrt{\frac{I_{s 3} I_{s 4}}{I_{s 1} I_{s 2}} \frac{1}{R} \frac{{(\frac{W}{L})}_{5}}{{(\frac{W}{L})}_{pwr}}} \sqrt{P_{diss} (1- \frac{V_{be}}{V_{ds}})} = K \sqrt{P_{diss} (1- \frac{V_{be}}{V_{ds}})} ≅ K \sqrt{P_{diss}}$
It has been shown that, if the base current of Q2 and the voltage drop across the diode D1 are neglected, the outgoing current from the collector of the transistor Q4 is proportional to the square root of the power dissipated through the power transistor. With the maximum dissipable power being known, (8) gives the value setting for the reference current generator Iref.
Were the contribution from the base current of Q2 a significant one (as may happen especially at low values of V_ds and if the (W/L)₅/(W/L)_pwr ratio is too high), it is possible to recover it as shown in Figure 2: Q6 must be identical with Q5, so as to generate the same current I₂; the current mirror formed of Q7 and Q8 recovers the base current of Q9, which is the same as that of Q2; in fact, Q2 and Q9 should have the same dimensions, so as to have the base currents exactly equated. In this case, the collector current of Q4 would be $I_{0} = K \sqrt{P_{diss} (1- \frac{V_{be}}{V_{ds}})} ≅ K \sqrt{P_{diss}}$
Figure 3 shows how the voltage drop across the diode D1 can be recovered in order to obtain an accurate measurement of the power dissipated by the power transistor, even at low values of V_ds. The additional current generator in parallel with R should generate a current equal to the voltage across the diode divided by the value of the resistor R, i.e. the same as is used to sense the voltage V_ds.
The major advantages to be derived from the inventive circuit can be summarized as follows:

accurate measurement of the instantaneous power dissipated by the power transistor;
simple circuit and least use of silicon area, especially when the configuration shown in Figure 1 is used;
temperature-wise performance tied to a minimal number of parameters: by suitably coupling Q5 to the power transistor, the only dependence on temperature will come from variations in the resistance of R, which can be arranged to have a low temperature coefficient by using a polycrystalline silicon resistor, for example.

Shown in Figure 4 is the power final stage of an audio amplifier comprising two MOS power transistors, both of the N-channel type, which are configured for push-pull operation. A pair of sensors according to the invention allow them to be protected without restricting their dynamic range.
It should be understood that modifications, integrations and substitutions of elements may be made unto the embodiment described in the foregoing, without departing from the protection scope of the appended claims.
For example, a P-channel MOS power transistor could be substituted for the N-channel MOS transistor of the upper half-stage in the diagram of Figure 4, with a PNP bipolar transistor and an NPN transistor being used for the transistors Q'2 and Q'4, respectively, and exchanging the diode D'1 with the resistor R.

Claims

A sensing circuit for sensing the instantaneous power dissipable through a power transistor (Pwr) in an integrated circuit, having a first terminal which is coupled to a potential reference (GND), a second terminal which forms an output terminal (OUT) of a power stage, and a control terminal (GATE) which is coupled to a circuit means for controlling and biasing the stage, characterized in that it comprises first (Q4) and second (Q5) transistors, each having first and second terminals and a control terminal, and a current mirror circuit (D1,Q2) having a first leg which includes a resistive element (R) and is connected between said output terminal (OUT) of the stage and the potential reference (GND), and a second leg connected between said output terminal (OUT) and a circuit node (N) to which the control terminal of the first transistor (Q4) is connected, the first terminal of the first transistor (Q4) being coupled to said output terminal (OUT) of the stage through a diode (D3) and the second terminal thereof being connected to the potential reference (GND) through a current generator (Iref) as well as to a terminal for connection to the stage control and bias circuit means, and the second transistor having its first and second terminals connected between the potential reference and said circuit node (N) and its control terminal connected to the control terminal (GATE) of the power transistor.
A sensing circuit according to Claim 1, characterized in that the first and second legs of the current mirror circuit respectively include a diode (D1) and a bipolar transistor (Q2).
A sensing circuit according to either Claim 1 or 2, characterized in that said first transistor (Q5) is of the bipolar type.
A sensing circuit according to any of Claims 1, 2 and 3, characterized in that said second transistor (Q5) is a homologous type of the power transistor (Pwr) whereto it is connected.
A sensing circuit for sensing the instantaneous power dissipable through a power transistor (Pwr) of the MOS type as claimed in any of Claims 1, 2, 3 and 4, characterized in that said second transistor (Q5) is also of the MOS type.
A monolithically integrated audio amplifier, characterized in that it comprises a final stage including at least one power transistor whose instantaneous power is sensed by means of a sensing circuit as claimed in any of Claims 1, 2, 3, 4 and 5.
An integrated circuit control system, characterized in that it comprises a power stage including at least one power transistor whose instantaneous power is sensed by means of a sensing circuit as claimed in any of Claims 1, 2, 3, 4 and 5.